Contribution of temperate germplasm to the performance of maize hybrids under stress and non-stress environments in South Africa

IF 1.1 Q3 AGRONOMY

South African Journal of Plant and Soil Pub Date : 2022-01-01 DOI:10.1080/02571862.2021.1994047

Sphiwokuhle Shandu, E. Gasura, K. Mashingaidze, J. Derera

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引用次数: 0

Abstract

Increases in genetic gains are crucial to maize breeding programmes. The objectives of this study were to identify higher-yielding and stable maize hybrids across stress and non-stress environments, to identify representative test environments for testing and selection of superior maize genotypes, and to determine the contribution of temperate maize germplasm in the performance of new tropical hybrids. Respectively 42 and 72 newly developed single-cross hybrids together with check hybrids were evaluated separately for grain yield performance across stress and non-stress environments, at four locations (Potchefstroom, Cedara, Vaalharts/Taung and Makhathini) in South Africa, in the 2014/15 and 2015/16 growing seasons (seasons 1 and 2, respectively). Additive main effects and multiplicative interaction (AMMI) and genotype + genotype × environment interaction (GGE) biplots were employed. In season 1, the hybrids MO17HtHtN × CML444 and I-39 × CML444 were the most stable and high-yielding genotypes after the ideal commercial check. In season 2, the hybrids FO215W × CML444, I-42 × CML444 and U71Y × CML444 were stable and high-yielding, with FO215W × CML444 being the most ideal. These stable hybrids would be the best suited for wide adaptation across non-stress and stress environments. Hybrids containing tropical CIMMYT testers were more stable than those derived from temperate Corn Belt material. The locations Potchefstroom and Vaalharts were the most suitable environments for evaluating the performance of these genotypes across the diverse environments.

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南非温带种质对胁迫和非胁迫环境下玉米杂交种性能的贡献

增加遗传增益对玉米育种计划至关重要。本研究的目的是在胁迫和非胁迫环境中鉴定高产和稳定的玉米杂交种，鉴定用于测试和选择优良玉米基因型的代表性试验环境，并确定温带玉米种质对新热带杂交种性能的贡献。分别在南非的四个地点（Potchefstroom、Cedara、Vaalharts/Taung和Makhathini），在2014/15和2015/16生长季节（分别为第1季和第2季），对42个和72个新开发的单交杂交种以及对照杂交种在胁迫和非胁迫环境下的粮食产量表现进行了评估。加性主效应和乘法相互作用（AMMI）与基因型 + 基因型 × 采用了环境相互作用（GGE）双标。在第1季中，杂交种MO17HtHtN × CML444和I-39 × CML444是经过理想的商业检测后最稳定和高产的基因型。在第二季中，混合动力车FO215W × CML444，I-42 × CML444和U71Y × CML444稳定且高产，FO215W × CML444是最理想的。这些稳定的杂交种最适合在非压力和压力环境中广泛适应。含有热带CIMMYT测试仪的杂交种比来自温带玉米带材料的杂交种更稳定。Potchefstroom和Vaalharts是最适合评估这些基因型在不同环境中表现的环境。

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来源期刊

South African Journal of Plant and Soil Agricultural and Biological Sciences-Plant Science

CiteScore

1.90

自引率

11.10%

发文量

期刊介绍： The Journal has a proud history of publishing quality papers in the fields of applied plant and soil sciences and has, since its inception, recorded a vast body of scientific information with particular reference to South Africa.